RECORDING MEDIUM, REPRODUCING APPARATUS, AND REPRODUCING METHOD
A recording medium records therein image data for distributing contents as element holograms with interference fringes generated by interference between an object beam representing the image data and a reference beam. The image data to be distributed which are recorded as the element holograms in the recording medium are reproduced by applying reference beams to the recording medium.
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This application is a divisional of application Ser. No. 11/415,157, filed May 2, 2006, which claims priority under 35 U.S.C. 119 to Japanese Patent Application JP 2005-148420 filed in the Japanese Patent Office on May 20, 2005, the entire contents of both of which are being incorporated herein by reference.
BACKGROUND OF THE INVENTIONThe present invention relates to a recording medium in the form of a hologram for recording data based on fringes produced by interference between an object beam from an image representing the data and a reference beam, and an apparatus for and a method of reproducing data recorded in the recording medium.
There are known in the art holographic recording mediums for recording various data based on fringes produced by interference between an object beam and a reference beam. It is also known in the art that the holographic recording mediums can have a high recording density for large storage capacity. The holographic recording mediums are considered to be useful as large-capacity storage mediums for storing computer data and AV (Audio-Video) contents data such as audio and video data, for example.
For recording data in a holographic recording medium, the data is converted into image data as two-dimensional page data. The data is displayed on a liquid crystal panel or the like, and a light beam that has passed through the liquid crystal panel, i.e., an object beam representing an image of the two-dimensional page data, is applied to the holographic recording medium. In addition, a reference beam is applied at a certain angle to the holographic recording medium. The object beam and the reference beam interfere with each other, producing fringes that can be recorded as a single element hologram. Therefore, a single element hologram is a recorded form of one two-dimensional page data.
Japanese patent laid-open No. 2005-32308 discloses an optical information recording process for achieving a large storage capacity on a holographic recording medium according to shift multiplexing and angle multiplexing. According to shift multiplexing, a colinear optical system is used to convert a reference beam into a convergent (or divergent) beam for recording a succession of overlapping element holograms on the holographic recording medium for an increased recording density. According to angle multiplexing, the angle of a reference beam is changed to record a number of overlapping element holograms at the same position on the holographic recording medium for an increased recording density.
SUMMARY OF THE INVENTIONThere is assumed a system employing a hologram memory in the shape of a sheet for recording computer data or AV contents data. In the system, the general user acquires the data recorded in the hologram memory with a reproducing apparatus serving as a hologram reader. The sheet-like hologram memory serves to record an array of closely packed element holograms on a flat medium surface thereof. The hologram reader is positioned in confronting relation to the medium surface for reading the data recorded as the element holograms from the hologram memory. Such a system is required to have the following features:
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- The hologram memory should have a certain large storage capacity.
- The hologram memory should easily be duplicated into a large number of copies.
- The hologram reader should be available inexpensively to the user and should have a simple makeup.
- The hologram reader should be able to reproduce recorded data stably.
Hologram memories that have heretofore been available in the art suffer the following problems: According to shift multiplexing and angle multiplexing referred to above, the hologram memories can have a storage capacity having a sufficiently large level, i.e., are considered to be able to store data of the order of terabytes. However, the system for providing the general user with computer data and AV contents data does not require hologram memories to have such a very large storage capacity. The existing hologram memories can have a storage capacity large enough to store computer data and AV contents data without the need for shift multiplexing and angle multiplexing. In addition, the shift multiplexing and angle multiplexing processes make it difficult to manufacture hologram readers inexpensively in a simple structure as the processes require reproducing apparatus compatible with them. For example, if data is recorded in a hologram memory according to the angle multiplexing process, then the hologram reader needs to have a structure for applying a reproducing reference beam at various angles to the hologram memory, and hence is large in size and high in cost. The shift multiplexing process is also disadvantageous in that it is difficult to produce a large number of duplicates according to a contact copying process. Though shift multiplexing and angle multiplexing are useful for a system with a very large storage capacity, they are not suitable for a system for distributing a large number of hologram memories to easily provide various data to the general user.
One solution is to record element holograms unoverlappingly on a planar hologram memory not based on shift multiplexing and angle multiplexing. Factors that are to be taken into account in such a recording process are a certain recording density, i.e., a storage capacity, and a crosstalk problem. For recording element holograms unoverlappingly on a planar hologram memory with an object beam and a reference beam applied at a certain angle, adjacent ones of the element holograms need to be spaced a sufficient distance from each other in order to reduce crosstalk which occurs when the recorded element holograms are read. If data is to be read from a hologram memory which stores an array of closely packed element holograms, then certain identification patterns may be embedded in the patterns of the respective element holograms, and a signal indicative of the positional relationship between the element holograms may be extracted from the identification patterns as a servo signal. Conversely, if element holograms are positioned at sufficiently spaced intervals for reducing crosstalk, then an intermittent signal is produced from the identification patterns and such an intermittent signal is not appropriate as a servo signal.
According to the present invention, there are provided a recording medium using holograms for achieving a certain storage capacity without suffering crosstalk problems, and an apparatus for and a method of stably reproducing recorded data from such a recording medium using holograms with a simple arrangement.
Specifically, there is provided in accordance with the present invention a recording medium for recording image data as element holograms with interference fringes generated by interference between an object beam representing the image data and a reference beam, including a first element hologram formed by interference fringes generated by interference between an object beam representing first data and a first reference beam applied at a first angle, and a second element hologram formed by interference fringes generated by interference between an object beam representing second data and a second reference beam applied at a second angle which is different from the first angle, the second element hologram overlapping the first element hologram such that the first element hologram has a portion remaining unoverlapped by the second element hologram.
According to the present invention, there is also provided an apparatus for reproducing data from a recording medium which records therein a first element hologram formed by interference fringes generated by interference between an object beam representing first data and a first reference beam applied at a first angle, and a second element hologram formed by interference fringes generated by interference between an object beam representing second data and a second reference beam applied at a second angle which is different from the first angle, the second element hologram overlapping the first element hologram such that the first element hologram has a portion remaining unoverlapped by the second element hologram, the apparatus including a reference beam applying means for applying reference beams to the recording medium respectively at the first angle and the second angle, a reproduced image detecting means for detecting hologram images reproduced from the recording medium which is irradiated with the reference beams applied by the reference beam applying means and outputting reproduced image signals representing the hologram images, a signal reading means for reading the reproduced image signals representing the hologram images detected by the reproduced image detecting means, a timing detecting means for detecting scanning times for scanning the element holograms recorded in the recording medium from the reproduced image output from the reproduced image detecting means when the recording medium is irradiated with the reference beams at the first angle and the second angle, and a control means for controlling the reference beam applying means to apply the reference beams at the respective angles corresponding to the element holograms at the scanning times detected by the timing detecting means, and controlling the reproduced image detecting means to detect and reproduce hologram images from the recording medium in response to the applied reference beams.
According to the present invention, there is further provided a method of reproducing data from a recording medium which records therein a first element hologram formed by interference fringes generated by interference between an object beam representing first data and a first reference beam applied at a first angle, and a second element hologram formed by interference fringes generated by interference between an object beam representing second data and a second reference beam applied at a second angle which is different from the first angle, the second element hologram overlapping the first element hologram such that the first element hologram has a portion remaining unoverlapped by the second element hologram, the method including the steps of simultaneously applying reference beams to the recording medium respectively at the first angle and the second angle, detecting hologram images reproduced from the recording medium which is irradiated with the reference beams and outputting reproduced image signals representing the hologram images, reading the reproduced image signals representing the hologram images which are detected, detecting scanning times for scanning the element holograms recorded in the recording medium from the reproduced image signals which are read, and applying the reference beams at the respective angles corresponding to the element holograms at the scanning times which are detected, and detecting and reproducing hologram images from the recording medium in response to the applied reference beams.
The reproducing apparatus reads element holograms each representing two-dimensional page data from the hologram recording medium to provide reproduced data. The recording medium, the recording apparatus, and the recording method according to the present invention make it possible to provide a storage medium system having a relatively large storage capacity for providing computer data and AV contents data. As the distance between element holograms is reduced, the recording density is increased. If the reference beam spot is greater than an element hologram in reproducing recorded data therefrom, then a reproduced image of an adjacent element hologram tends to be also detected, resulting in crosstalk. Attention is drawn to the fact that a reproduced image of a recorded element hologram is obtained from a hologram memory when a reference beam is applied to the element hologram at the same angle as when a reference beam is applied to record the element hologram. If element holograms recorded by recording reference beams applied at different angles are positioned adjacent to each other in the hologram recording medium, then the recording density can be increased while reducing crosstalk between the adjacent element holograms. Specifically, the recording density is increased and the crosstalk is reduced if element holograms of different types ranging from the first type to the nth type are successively recorded in overlapping relation with each element hologram having an unoverlapping area not overlapping other element holograms. The reproducing apparatus for reading data from the hologram recording medium with the element holograms being thus recorded therein has a plurality of reference beam applying means for applying a plurality of reference beams, and controls the times to energize the reference beam applying means to read crosstalk-free or low-crosstalk signals from the element holograms. The reproducing apparatus is also capable of detecting signals representing the positional relationship between the element holograms and generating an appropriate timing signal.
Since the hologram recording medium according to the present invention can greatly reduce crosstalk from adjacent element holograms, the hologram recording medium may be constructed as a high-density hologram array and allow a servo signal indicative of the distance between adjacent element holograms, the direction thereof, and scanning times thereof to be read with ease. Because the reproducing apparatus has the plural reference beam applying means for applying a plurality of reference beams, and controls the times to energize the reference beam applying means to read crosstalk-free or low-crosstalk signals from the element holograms. As the reproducing apparatus is also capable of detecting signals representing the positional relationship between the element holograms, it can generate an appropriate timing signal. The hologram recording medium with the element holograms recorded therein according to the present invention can easily be duplicated into a large number of copies according to a contact copying process.
According to the present invention, therefore, the hologram recording medium can have a certain large storage capacity and can easily be duplicated into a large number of copies, the reproducing apparatus can have a simple makeup and is able to reproduce recorded data stably. The reproducing apparatus is suitable for use in a system wherein computer data and AV contents data are recorded in the hologram recording medium, such hologram recording mediums are widely distributed, and the general user acquires the data recorded in the hologram recording medium using the reproducing apparatus.
The above and other objects, features, and advantages of the present invention will become apparent from the following description when taken in conjunction with the accompanying drawings which illustrate preferred embodiments of the present invention by way of example.
The embodiments of the present invention will be described below in the following order of topics:
[1. Recording and reproducing process of hologram memory]
[2. Hologram memory according to the embodiment]
[3. Reproducing apparatus arrangement]
[4. Reproducing operation on hologram memory]
[1. Recording and reproducing process of hologram memory]
A basic recording and reproducing process of a hologram memory 3 according to an embodiment will be described below with reference to
The element hologram recorded in the hologram memory 3 is reproduced as shown in
The hologram memory 3 according to the present embodiment which performs the above basic recording and reproducing process will be described below.
According to the embodiment, data to be recorded, each in the form of a data block as two-dimensional page data, are successively sorted alternately as data of a first type (data Da) and data of a second type (data Db). For example, as shown in
At the time of recording the data of the data block BLK sorted as data Da, as shown in
At the time of recording the data of the data block BLK sorted as data Db, as shown in
In this manner, the data Da, Db are alternately recorded in the hologram memory 3 while the recording reference beams L3A, L3B are being alternately applied to the hologram memory 3. At this time, the hologram memory 3 (hologram material) is positionally displaced (or the recording optical mechanism is positionally displaced) by a displacing mechanism, not shown, to record successive element holograms at slightly displaced positions on the surface of the hologram memory 3. Therefore, element holograms of the first type with regard to the data Da and element holograms of the second type with regard to the data Db are successively recorded in the hologram memory 3 with the element holograms of the first and second types partly overlapping and unoverlapping each other.
For recording element holograms 8A, 8B as shown in
If the hologram memory 3 is in the form of a disc for recording element holograms 8A, 8B along circumferential tracks on the hologram memory 3, then the element holograms 8A, 8B may be recorded in the format shown in
The element holograms 8A, 8B recorded in the hologram memory 3 are reproduced as follows: For reproducing the element holograms 8A, 8B that are recorded in the hologram memory 3 as shown in
Stated otherwise, the distances by which the beam spot and the hologram memory 3 are relatively displaced when the element holograms BA, 8B are recorded as shown in
As shown in
As shown in
For obtaining a reproduced image of an element hologram, the reproducing reference beam spots SPA, SPB have to be a size equal to or greater than the size of the element hologram. Since the center of the element hologram and the center of the reference beam spots SPA, SPB may not necessarily be aligned with each other when the element hologram is scanned for reproducing data therefrom, the size of the reference beam spots SPA, SPB actually needs to be greater than the size of the element holograms. The element holograms 8A, 8B which are successively recorded while overlapping each other in the overlapping areas W and having the respective unoverlapping areas NWa, NWb contribute to the reduction of crosstalk. Specifically, because a certain distance is provided between element holograms in order to provide the unoverlapping area NWa, when the reference beam spot SPA is applied near the center of an element hologram 8A, even if the reference beam spot SPA is of a diameter greater than the diameter of the element hologram 8A, the reference beam spot SPA does not reach an element hologram 8A of the same type which is positioned across an element hologram 8B from the element hologram 8A.
The foregoing details will be summarized as follows: By successively recording element holograms based on two-dimensional page data in the hologram memory 3, a medium having a relatively large capacity for recording computer data and AV contents data is realized. As the distance between element holograms is reduced, the recording density is increased. If the reference beam spot is greater than an element hologram in reproducing recorded data therefrom, then a reproduced image of an adjacent element hologram tends to be also detected, resulting in crosstalk. This problem occurs also on Lippmann holograms employing a photopolymer or embossed holograms produced as CGH (Computer-Generated Holograms).
According to the present embodiment, attention is drawn to the fact that a reproduced image of a recorded element hologram is obtained when a reference beam is applied to the element hologram at the same angle as when a reference beam is applied to record the element hologram. If element holograms 8A, 8B recorded by recording reference beams L3A, L3B applied at different angles are positioned adjacent to each other in the hologram memory 3, then the recording density can be increased while reducing crosstalk between the adjacent element holograms. Specifically, when the element hologram 8A is to be reproduced, the reproducing reference beam L4A is used. Since the angle of the reproducing reference beam L4A is widely different from the angle of the recording reference beam L3B applied to record the element hologram 8B, no signal is reproduced from the element hologram 8B even if the reproducing reference beam L4A is applied to the element hologram 8B. Therefore, crosstalk is not increased even if the distance between adjacent holograms is increased. Furthermore, inasmuch as the size of the reproducing reference beam spots SPA, SPB, the size of the element holograms 8A, 8B, and the distances d1, d2 between the element holograms 8A, 8B are established as described above with reference to
According to the present embodiment, therefore, though the element holograms 8A, 8B are recorded in a high density, data essentially free of crosstalk can be read therefrom. The element holograms 8A, 8B are recorded overlappingly in the overlapping areas W. It has already been known in the art that if the hologram memory 3 is made of a photopolymer, then it is possible to record a plurality of element holograms overlappingly. Such overlapping recording is apparent because a plurality of element holograms are recorded overlappingly according to shift multiplexing and angle multiplexing as described above. For reading reproducing images of respective element holograms at times for eliminating crosstalk, the reproducing apparatus (hologram reader) needs to be able to determine those times (scanning times). The scanning times are determined using the identification marks described above. Specifically, the identification marks are provided as the white area Wa and the black area Ba in the two-dimensional page data referred to as the data Da, and as the black area Bb and the white area Wb in the two-dimensional page data referred to as the data Db. The identification marks will be described later with respect to a hologram reader, which will be described later with reference to
According to the present embodiment, the element holograms 8A, 8B are recorded using the respective recording reference beams L3A, L3B. The hologram memory 3 can be copied into a large number of duplicates according to a contact copying process. Specifically, a hologram blank is held in close contact with the hologram memory 3 as a copy master, and a reference beam is applied to them at the same angle as the recording reference beam L3A to transfer the element holograms 8A from the copy master to the hologram blank and a reference beam is applied to them at the same angle as the recording reference beam L3B to transfer the element holograms 8B from the copy master to the hologram blank.
In the above embodiment, two recording reference beams L3A, L3B applied at different angles have been described as reference beams. However, it is also possible to use a greater number of reference beams at different angles.
Then, as with the linear array of element holograms shown in
A hologram reader 20 as a reproducing apparatus for reproducing data recorded in the hologram memory 3 described above with reference to
First, structural details of the hologram reader, generally denoted by 20 in
The hologram reader 20 has a collimator lens 4, an imager 5, and two reference beam sources 7A, 7B for reading recorded data from the hologram memory 3. The reference beam source 7A is located for emitting a reproducing reference beam L4A to the hologram memory 3 at the same angle as the recording reference beam L3A. The reference beam source 7B is located for emitting a reproducing reference beam L4B to the hologram memory 3 at the same angle as the recording reference beam L3B. The collimator lens 4 guides reproduced image light from the hologram memory 3 to the imager 5. The imager 5 includes a solid-state imaging device array such as a CMOS image sensor, a CCD image sensor, or the like. The imager 5 detects the reproduced image light applied through the collimator lens 4 and outputs an electric reproduced image signal representative of the reproduced image light.
The reference beam sources 7A, 7B, which may include LEDs (Light Emitting Diodes), are energized to emit light by a light emission driver 30. When the hologram reader 20 is to reproduce recorded data from the hologram memory 3, the light emission driver 30 turns on and off the reference beam sources 7A, 7B at predetermined respective times according to instructions from the system controller 21.
A hologram scan controller 22 controls operation of the imager 5 and processes the reproduced image signal generated by the imager 5. Specifically, the hologram scan controller 22 supplies the imager 5 with a transfer timing signal, a transfer address signal, etc. to successively transfer a reproduced image signal which is generated by the solid-state imaging device array during an image capturing process. The hologram scan controller 22 then performs various processing processes, including a sampling process, an AGC process, an A/D conversion process, etc. on the reproduced image signal transferred from the imager 5, and outputs the processed reproduced image signal.
The imager 5 supplies signals SA, SB from sensing areas thereof, which correspond to the identification marks assigned to the two-dimensional page data as described above, to a computing unit 32. The computing unit 32 supplies a differential signal (SA-SB) which represents the difference between the signals SA, SB through the hologram scan controller 22 to the system controller 21. As described later, the system controller 21 determining scanning times based on the differential signal (SA-SB), controls the hologram scan controller 22 to read reproduced image signals from the imager 5 and to store the read image signals into a DRAM (Dynamic Random Access Memory) 24, and also controls the reference beam sources 7A, 7B for emitting the reference beams.
The digital reproduced image signal output from the hologram scan controller 22 is stored in the DRAM 24 under the control of a memory controller 23. The memory controller 23 controls the transfer of data to be stored in the DRAM 24 and a flash memory 25, and also controls the writing and reading of data to and from the DRAM 24 and the flash memory 25. The reproduced image signal that is stored in the DRAM 24 is processed by a hologram image processor 27 and a signal processor 28. An SRAM (Static Random Access Memory) 29 is used to exchange the processed image signal and information required to process the image signal between the hologram image processor 27 and the signal processor 28, and the system controller 21. The flash memory 25 stores settings, coefficients, and various control parameters that are required for signal processing in the hologram image processor 27 and the signal processor 28.
The hologram image processor 27 corrects the reproduced image signal for optical distortions representing data variations due to optical reasons, adjusts the brightness of the reproduced image signal, corrects the reproduced image signal for image position displacements, and corrects the reproduced image signal for image angle displacements. The hologram image processor 27 also converts the reproduced image signal into a binary signal having two white and black values if the reproduced image signal output from the imager 5 represents gradation image data. This is because the data to be read from the hologram memory 3 are two-dimensional page data as two white and black values converted from the original recorded data.
The signal processor 28 performs a decoding process and an error-correcting process on the binary reproduced image signal representing a two-dimensional image pattern, thereby producing the original data. Specifically, the signal processor 28 generates a single data block BLD as shown in
The data generated by the signal processor 28 are transferred as reproduced data from the hologram memory 3 through an external interface 26 to an external device 100 such as a personal computer, an AV device such as an audio player or a video player, or a cellular phone. The external interface 26 may be a USB interface or an interface according to standards other than the USB standards. The user can use the reproduced data from the hologram memory 3 through the external device 100. For example, the user may use computer data on a personal computer or may reproduce AV contents data on an AV device or a cellular phone.
A medium drive for recording data on a certain recording medium may be connected to the hologram reader 20, and the reproduced data obtained by the signal processor 28 may be recorded on the recording medium by the medium drive. The recording medium may be an optical disc, a magnetooptical disc, or the like. For example, the recording medium may be recordable discs according to various formats including a CD (Compact Disc) format, a DVD (Digital Versatile Disc) format, Blu-Ray Disc format, an MD (Mini Disc) format, etc. If any of the discs of these types are used as the recording discs, then the medium drive performs an encoding process, an error-correcting code process, a compression process, etc. depending on the discs on audio data and records the processed audio data on the discs. The recording disc may also be a hard disc. If the recording disc is a hard disc, then the medium drive includes an HDD (Hard Disc Drive). The recording disc may alternatively be a portable memory card with a built-in solid-state memory or a built-in solid-state memory. If the recording disc is such a portable memory card or a built-in solid-state memory, then the medium drive includes a recording unit for recording data in a portable memory card or a built-in solid-state memory. The medium drive processes audio data according to necessary signal processing processes and records the processed audio data in the portable memory card or the built-in solid-state memory.
The hologram reader 20 may also have an audio data reproducing and outputting system and a video data reproducing and outputting system for decoding and outputting AV contents data that have been reproduced from a recording medium by the medium drive. Audio data reproduced by the medium drive may be transferred through the external interface 26 to the external device. If the reproduced data are recorded in a portable recording medium such as a CD, a DVD, a Blu-Ray disc, an MD, a memory card, or the like, then the recording medium may be played on the external device for the user to use the reproduced data read from the hologram memory 3.
[4. Reproducing Operation on Hologram Memory]The hologram reader 20 performs the reproducing process described above with reference to
In the present embodiment, the scanning operation of the hologram reader 20 is not limited to any specific process, but may be performed according to various processes. For example, the hologram reader 20 may have a loading mechanism for loading the hologram memory 3, and may also have a scanning mechanism for moving the collimator lens 4 and the imager 5 with respect to the hologram memory 3 loaded by the loading mechanism. Alternatively, the hologram reader 20 may move the hologram memory 3 with respect to a fixed reading position provided by the collimator lens 4 and the imager 5. Further alternatively, the hologram reader 20 may be constructed as a small-size device, and the user may hold the hologram reader 20 by hand and move the hologram reader 20 over the surface of the hologram memory 3. In any of these scanning schemes, the reading position provided by the collimator lens 4 and the imager 5 for reading a reproduced image is moved over the element holograms 8A, 8B as shown in
A signal SA shown in
The process of the system controller 21 for reading recorded data from the hologram memory 3 will be described below with reference to the flowchart shown in
The signals SA, SB and the differential signal (SA-SB) that are generated at this time are shown in
As the element holograms 8A, 8B are successively scanned as shown in
The differential signal (SA-SB) generated by the computing unit 32 is supplied to the system controller 21. The system controller 21 compares the absolute value of the differential signal (SA-SB) with a threshold value th in step F102. If |SA-SB|>th, then control goes to step F103. In step F103, the system controller 21 determines whether the differential signal (SA-SB) is of a positive value or a negative value. If the differential signal (SA-SB) is of a positive value, then control goes to step S104 in which the system controller 21 turns off the reference beam source 7B and turns on only the reference beam source 7A to apply the reference beam L4A to the hologram memory 3. In step F105, the system controller 21 controls the hologram scan controller 22 to read a reproduced image signal generated from the imager 5 only during the period of the reference beam L4A as the reproduced image signal of the element hologram 8A (data Da). If the differential signal (SA-SB) is of a negative value, then control goes to step S106 in which the system controller 21 turns off the reference beam source 7A and turns on only the reference beam source 7B to apply the reference beam L4B to the hologram memory 3. In step F107, the system controller 21 controls the hologram scan controller 22 to read a reproduced image signal generated from the imager 5 only during the period of the reference beam L4B as the reproduced image signal of the element hologram 8B (data Db).
The reproduced image signal read in step F105 or F107 is processed by the hologram scan controller 22, and then stored in the DRAM 24 in step F108. In step F109, the system controller 21 determines whether the reading of reproduced image signals representing two-dimensional page data from all the element holograms has been completed or not. If not completed, then control goes back to step F101 to continue the scanning operation. When the reading of reproduced image signals from all the element holograms has been completed, the reading of all the data blocks BLK shown in
When the reading process has been completed, the system controller 21 reconstructs the data read from the hologram memory 3. Specifically, the system controller 21 controls the hologram image processor 27 and the signal processor 28 to process the reproduced image signals of all the data blocks BLK to reconstruct the recorded original data. In step F111, the system controller 21 instructs the light emission driver 30 to turn off the reference light sources 7A, 7B for terminating the emission of the reproducing reference beams L4A, L4B. The process of reading recorded data from the hologram memory 3 is put to an end.
The timing to read data in steps F105, F107 will be described below with reference to
If the differential signal (SA-SB) is of a positive value in step F103, i.e., during the period in which the differential signal (SA-SB) exceeds the positive threshold value th shown in
If the differential signal (SA-SB) is of a negative value in step F103, i.e., during the period in which the differential signal (SA-SB) exceeds the negative threshold value th shown in
As described above, the hologram reader 20 can read high-quality reproduced signals of the element holograms 8A, 8B from the hologram memory 3 in which the element holograms 8A, 8B are successively recorded such that adjacent ones of the element holograms 8A, 8B overlap each other in the overlapping area W (see
Accordingly, the hologram reader 20 is of a simple structural arrangement and has a stable data reproducing capability. The hologram reader 20 is suitable for use in a system wherein computer data and AV contents data are recorded in the hologram memory 3, such hologram memories 3 are widely distributed, and the general user acquires the data recorded in the hologram memory 3 using the hologram reader 20.
In the embodiment shown in
In the above embodiment, the hologram reader 20 reads data from the hologram memory 3 in which the element holograms 8A, 8B are recorded as shown in
The reproducing apparatus (hologram reader) is not limited to the arrangement shown in
Although certain preferred embodiments of the present invention have been shown and described in detail, it should be understood that various changes and modifications may be made therein without departing from the scope of the appended claims.
Claims
1. An apparatus for reproducing data from a recording medium which records therein a first element hologram formed by interference fringes generated by interference between an object beam representing first data and a first reference beam applied at a first angle, and a second element hologram formed by interference fringes generated by interference between an object beam representing second data and a second reference beam applied at a second angle which is different from said first angle, said second element hologram overlapping said first element hologram such that said first element hologram has a portion remaining unoverlapped by said second element hologram, said apparatus comprising:
- reference beam applying means for applying reference beams to said recording medium respectively at said first angle and said second angle;
- reproduced image detecting means for detecting hologram images reproduced from said recording medium which is irradiated with the reference beams applied by said reference beam applying means and outputting reproduced image signals representing said hologram images;
- signal reading means for reading the reproduced image signals representing said hologram images detected by said reproduced image detecting means;
- timing detecting means for detecting scanning times for scanning the element holograms recorded in said recording medium from the reproduced image output from said reproduced image detecting means when said recording medium is irradiated with the reference beams at said first angle and said second angle;
- control means for controlling said reference beam applying means to apply the reference beams at the respective angles corresponding to the element holograms at the scanning times detected by said timing detecting means, and controlling said reproduced image detecting means to detect and reproduce hologram images from said recording medium in response to the applied reference beams; and
- memory means for storing the reproduced image signals read by said signal reading means.
2. The apparatus according to claim 1, wherein each of reproduced image signals representing adjacent element holograms which are disposed in overlapping relation has an identifier for identifying each of the adjacent element holograms, said apparatus further comprising:
- identifier detecting means for detecting said identifier.
3. The apparatus according to claim 2, wherein said timing detecting means detects scanning times based on the identifier detected by said identifier detecting means.
4. The apparatus according to claim 3, wherein said identifier detecting means detects said identifier based on a brightness in a predetermined area of each of said reproduced image signals.
5. The apparatus according to claim 4, wherein said identifier detecting means detects said identifier based on a combination of brightnesses in a plurality of predetermined areas of each of said reproduced image signals.
6. A method of reproducing data from a recording medium which records therein a first element hologram formed by interference fringes generated by interference between an object beam representing first data and a first reference beam applied at a first angle, and a second element hologram formed by interference fringes generated by interference between an object beam representing second data and a second reference beam applied at a second angle which is different from said first angle, said second element hologram overlapping said first element hologram such that said first element hologram has a portion remaining unoverlapped by said second element hologram, said method comprising the steps of:
- simultaneously applying reference beams to said recording medium respectively at said first angle and said second angle;
- detecting hologram images reproduced from said recording medium which is irradiated with the reference beams and outputting reproduced image signals representing said hologram images;
- reading the reproduced image signals representing said hologram images which are detected;
- detecting scanning times for scanning the element holograms recorded in said recording medium from the reproduced image signals which are read;
- applying the reference beams at the respective angles corresponding to the element holograms at the scanning times which are detected, and detecting and reproducing hologram images from said recording medium in response to the applied reference beams; and
- storing the reproduced image signals which are read into memory means.
7. The method according to claim 6, wherein each of reproduced image signals representing adjacent element holograms which are disposed in overlapping relation has an identifier for identifying each of the adjacent element holograms, said method further comprising the step of:
- detecting said identifier.
8. The method according to claim 7, wherein said step of detecting scanning times detects the scanning times based on said identifier which is detected.
9. The method according to claim 8, wherein said step of detecting said identifier detects said identifier based on a brightness in a predetermined area of each of said reproduced image signals.
10. The method according to claim 9, wherein said step of detecting said identifier detects said identifier based on a combination of brightnesses in a plurality of predetermined areas of each of said reproduced image signals.
Type: Application
Filed: Jan 14, 2008
Publication Date: Aug 7, 2008
Patent Grant number: 7697178
Applicant: Sony Corporation (Minato-ku)
Inventor: Yoshiyuki TERAOKA (Kanagawa)
Application Number: 12/014,005
International Classification: G03H 1/28 (20060101);